辽西春季解冻期褐土工程堆积体坡面侵蚀特征

doi:10.16843/j.sswc.2022.03.008

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Abstract [Background] Soil erosion in production construction projects is a typical man-made accelerated erosion. Fuxin city is located in the semi-arid region of western Liaoning, with brown soil and sandy soil as the main soil types, and is the most fragile ecological environment with serious soil erosion. Therefore, this paper selected the accumulation body of the Xihe River regulation project in Fuxin city as the research object, and studied the slope sediment characteristics, hydrodynamic parameters and erosion ditch morphology of the accumulation body under the influence of freeze-thaw, aiming to provide basic parameters and technical basis for the layout of soil and water conservation measures in production and construction projects.[Methods] The soil used in this experiment was obtained from the river soil of the river regulation project in Fuxin city, Haizhou district, and after sieving and preparation, it was filled into the soil tank in layers of 5 cm. The erosion process of slope of cinnamon soil engineering in spring thawing period was studied by simulating water flushing test in laboratory. Measurement of flow rate by dyeing method (KMnO₄) and erosion gully morphology by straight edge. SPSS 20 was used for data processing, and Autocad2012 and Excel were used for drawing.[Results] Under different thawing times, the sand production process on the slope of the mound all showed a trend of first increasing and then stabilizing.The average increase in sand production on slopes under the influence of freezing and thawing was 22.5%, which increased the erosion of the slopes of the engineered accumulation.The longer the thaw was, the more severe the slope erosion was.The different slopes affected by freezing and thawing showed a decrease in the Daicy-Weisbach coefficient of resistance f by 75.40% and 71.33% and an increase in the Froude number Fr by 44.4% and 32%, compared to the control slope.There was a very significanty positive correlation between the amount of erosion and the average cross-sectional area and the water scouring amount, a very significanty negative correlation between f and the water scouring amount, and a significanty positive correlation between Fr and water scouring amount. Erosion gullies on the slopes of freeze-thaw affected mounds developed in a "wide deep-narrow deep-wide shallow" pattern down to the top of the slope.[Conclusions] In the northern areas of China affected by freezing and thawing, the freezing and thawing effect will accelerate the flow rate of slope runoff and reduce the slope resistance parameter.During erosion, the slope of an engineered stockpile presents a faster runoff rate and less resistance to runoff than a slope not affected by freezing and thawing, resulting in more intense erosion.

Key words： freeze-thaw action engineering accumulation morphological characteristics hydraulic parameters

Received: 15 December 2021

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S157.1

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	Articles by authors
	JI Zhengquan
	Lü Gang
	LI Kunheng
	WANG Shuang
	LIU Shuang
	ZHU Su

Cite this article:

JI Zhengquan,Lü Gang,LI Kunheng, et al. Slope erosion characteristics of brown soil engineering accumulation in spring thawing period in western Liaoning[J]. SSWC, 2022, 20(3): 62-71.

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http://journal12.magtechjournal.com/Jweb_stbc/EN/10.16843/j.sswc.2022.03.008 OR http://journal12.magtechjournal.com/Jweb_stbc/EN/Y2022/V20/I3/62

[1]	WANG Tian,LI Peng,LIU Ying,et al. Experimental investigation of freeze-thaw meltwater compound erosion and Runoff energy consumption on loess slopes[J]. Catena,2020(185):104310.
[2]	范昊明,张瑞芳,周丽丽,等.气候变化对东北黑土冻融作用与冻融侵蚀发生的影响分析[J].干旱区资源与环境,2009,23(6):48. FAN Haoming,ZHANG Ruifang,ZHOU Lili,et al.Impact of climate change on freeze-thaw function and freeze-thaw erosion in black soil region of Northeast China[J]. Journal of Arid Land Resources and Environment, 2009,23(6):48.
[3]	范昊明,蔡强国.冻融侵蚀研究进展[J].中国水土保持科学,2003,1(4):50. FAN Haoming,CAI Qiangguo.Review of research progress in freeze-thaw erosion[J].Science of Soil and Water Conservation, 2003,1(4):50.
[4]	MOSTNGHIMI S,YOUNG R A,WILTS A R.Effects of frost action on soil aggregate stability[J].Transactions of the Asae, 1988,31(2):435.
[5]	黄海,田尤,刘建康,等.藏东地区斜坡土壤冻融侵蚀力学机制及敏感性分析[J].地理学报,2021,76(1):87. HUANG Hai,TIAN You,LIU Jiankang,et al. The mechanism and sensitivity analysis of soil freeze-thaw erosion on slope in eastern Tibet[J]. Acta Geographica Sinica, 2021,76(1):87.
[6]	李占斌,李社新,任宗萍,等.冻融作用对坡面侵蚀过程的影响[J].水土保持学报,2015,29(5):56. LI Zhanbin,LI Shexin,REN Zongping,et al.Effects of freeze-thaw on hillslope erosion process[J]. Journal of Soil and Water Conservation, 2015,29(5):56.
[7]	付金霞,王静,张宝利,等.砒砂岩原状坡面不同季节复合侵蚀动力的贡献研究[J].农业工程学报,2020,36(11):66. FU Jinxia,WANG Jing,ZHANG Baoli,et al.Contributions of composite erosion forces on undisturbed Pisha sandstone slope in different seasons[J].Transactions of the CSAE, 2020, 36(11):66.
[8]	张科利,刘宏远.东北黑土区冻融侵蚀研究进展与展望[J].中国水土保持科学,2018,16(1):17. ZHANG Keli,LIU Hongyuan.Research progresses and prospects on freeze-thaw erosion in the black soil region of northeast China[J]. Science of Soil and Water Conservaton,2018,16(1):17.
[9]	张攀,姚文艺,刘国彬,等.土壤复合侵蚀研究进展与展望[J].农业工程学报,2019,35(24):154. ZHANG Pan,YAO Wenyi,LIU Guobin,et al.Research progress and prospects of complex soil erosion[J].Transactions of the CSAE, 2019, 35(24):154.
[10]	魏霞,李勋贵,HUANG C H.交替冻融对坡面产流产沙的影响[J].农业工程学报,2015,31(13):157. WEI Xia, LI Xungui, HUANG Chihua.Impacts of freeze-thaw cycles on runoff and sediment yield of slope land[J]. Transactions of the CSAE, 2015, 31(13):157.
[11]	冯君园,蔡强国,李朝霞,等.高海拔寒区融水侵蚀研究进展[J].水土保持研究,2015,22(3):331. FENG Junyuan, CAI Qiangguo, LI Chaoxiang, et al. Research progresses of water erosion in the high altitude and cold regions of China[J]. Research of Soil and Water Conservation,2015,22(3):331.
[12]	WU Y Y,WEI O Y, HAO Z C, et al. Assessment of soil erosion characteristics in response to temperature and precipitation in a freeze-thaw watershed[J]. Geoderma,2018(328):56.
[13]	金万鹏,范昊明,刘博,等.冻融交替对黑土团聚体稳定性的影响[J].应用生态学报,2019,30(12):4195. JIN Wanpeng, FAN Haoming,LIU Bo,et al.Effects of freeze-thaw cycles on aggregate stability of black soil[J]. Chinese Journal of Applied Ecology,2019,30(12):4195.
[14]	丁鹏玮,戴全厚,姚一文,等.工程堆积体上不同植被类型枯落物和土壤水文效应[J].水土保持学报,2021,35(4):135. DING Pengwei,DAI Quanhou,YAO Yiwen,et al.Hydrological effects of litter and soil of different vegetation types on engineering accumulation[J]. Journal of Soil and Water Conservation, 2021,35(4):135.
[15]	康宏亮,王文龙,薛智德,等.陕北风沙区含砾石工程堆积体坡面产流产沙试验[J].水科学进展,2016,27(2):256. KANG Hongliang,WANG Wenlong,XUE Zhide,et al.Experimental study on runoff and sediment yield from engineering deposition with gravel in the northern windy-sandy region,Shaanxi[J].Advances in Water Science, 2016,27(2):256.
[16]	张乐涛,高照良,李永红,等.模拟径流条件下工程堆积体陡坡土壤侵蚀过程[J].农业工程学报,2013,29(8):145. ZHANG Letao, GAO Zhaoliang, LI Yonghong, et al.Soil erosion process of engineering accumulation in steep slope under simulated runoff conditions[J].Transactions of the CSAE, 2013, 29(8):145.
[17]	李建明,王文龙,王贞,等.神府煤田废弃堆积体新增水土流失研究[J].自然灾害学报,2014,23(2):239. LI Jianming,WANG Wenlong,WANG Zhen,et al. Study on newly increased soil and water loss from waste accumulation in Shenfu coal-field[J].Journal of Natural Disasters, 2014,23(2):239.
[18]	李忠武,蔡强国,吴淑安,等.内昆铁路施工期不同下垫面土壤侵蚀模拟研究[J].水土保持学报,2001,15(2):5. LI Zhongwu,CAI Qiangguo,WU Shu'an,et al. Simulation study on soil erosion of different underlying surface in construction period of Neikun railway[J]. Journal of Soil and Water Conservation, 2001,15(2):5.
[19]	李坤衡,吕刚,秦伟,等.辽西半干旱区典型城市土壤入渗特性[J].中国水土保持科学,2020,18(6):53. LI Kunheng,LÜ Gang, QIN Wei,et al.Infiltration characteristics of urban soil in semi-arid area of western Liaoning province[J]. Science of Soil and Water Conservation, 2020,18(6):53.
[20]	吕刚,王磊,张卓,等.辽西低山丘陵区不同年龄荆条冠层截留降雨模拟实验研究[J].生态学报,2019,39(17):6372. LÜ Gang,WANG Lei,ZHANG Zhuo,et al.Simulated and experimental study on rainfall interception of different aged Vitex negundo var. heterophylla canopies in the low mountains and hills of western Liaoning[J].Acta Ecologica Sinica,2019,39(17):6372.
[21]	吕刚,刘雅卓,陈鸿,等.褐土和棕壤坡耕地细沟侵蚀过程及侵蚀产沙特征[J].水土保持学报,2019,33(3):64. LÜ Gang,LIU Yazhuo,CHEN Hong,et al.Rill erosion process and sediment yield characteristics in cinnamon soil and brown soil slope farmland[J]. Journal of Soil and Water Conservation,2019,33(3):64.
[22]	刘晓娇,陈仁升,刘俊峰,等.黄河源区积雪变化特征及其对春季径流的影响[J].高原气象,2020,39(2):226. LIU Xiaojiao,CHEN Rensheng,LIU Junfeng,et al. Variation of snow cover and its influence on spring runoff in the source region of Yellow River[J]. Plateau Meterology,2020,39(2):226.
[23]	甘凤玲,何丙辉,覃自阳.喀斯特槽谷区的顺/逆层坡面对水动力学参数的影响[J].土壤学报,2019,56(4):825. GAN Fengling,HE Binghui,TAN Ziyang,et al.Effect of bedding slope on hydrodynamic parameters in typical Karst Valley[J]. Acta Pedologica Sinica,2019,56(4):825.
[24]	李坤衡,焦剑,秦伟,等.东北典型黑土区土壤侵蚀过程顺坡起垄垄沟水力学特征分析[J].水土保持学报,2021,35(3):77. LI Kunheng,JIAO Jian,QIN Wei,et al.Hydrauliacharacteristics of longitudinal ridges and furrows in soil erosion in the typical black soil area of Northeast China[J]. Journal of Soil and Water Conservation, 2021,35(3):77.
[25]	程圣东,杭朋磊,李占斌,等.初始解冻深度对冻融坡面侵蚀产沙过程的影响[J].西安理工大学学报,2018,34(3):257. CHENG Shengdong,HANG Penglei,LI Zhanbin,et al.Study of the influence of initial thawing depth on the erosion and sediment yield processes on freezing-thawing slope[J]. Journal of Xi'an University of Technology, 2018,34(3):257.
[26]	KOK H,MCCOOL D K.Quantifying freeze/thaw-induced variability of soil strength[J].Transactions of the ASAE, 1990,33(2):501.
[27]	范昊明,钱多,周丽丽,等.冻融作用对黑土力学性质的影响研究[J].水土保持通报,2011,31(3):81. FAN Haoming,QIAN Duo,ZHOU Lili,et al.Effects of freeze-thaw cycle on mechanical properties of black soil[J].Bulletin of Soil and Water Conservation, 2011,31(3):81.
[28]	速欢,王文龙,康宏亮,等.露天矿排土场平台-边坡系统侵蚀形态及径流产沙特征[J].应用生态学报,2020,31(9):3194. SU Huan,WANG Wenlong,KANG Hongliang,et al.Erosion morphology and the characteristics of runoff and sediment yielding in platform-slope system of opencast coal mine[J].Chinese Journal of Applied Ecology, 2020,31(9):3194.